KR100513328B1 - Apparatus and method of converting a series of data words into a modulated signal - Google Patents

Abstract

The present invention relates to an apparatus and method for converting a series of data words into a modulated signal. The present invention relates to a plurality of codeword sequences by adding different digital words to input data words, and then coding them in a predetermined manner such as an NRZI coding scheme. And calculate the digital sum value (DSV) for the plurality of codeword sequences, as well as the K penalty according to the number of '0's present between consecutive' 1's in each bit. Calculates and writes to a recording medium such as a magnetic disk, a magneto-optical disk or an optical disk by selecting a codeword sequence for recording by selecting one codeword sequence having a relatively small sum of the calculated DSV and K penalties. When selecting a codeword to be used, not only the DSV but also the number of consecutive '0's (Zeros) between' 1 'and' 1 'in the data bit string of the codeword are limited, so that the playback PLL can be stabilized. Very useful inventions that are able to perform playback from operating normally.

Description

Apparatus and method of converting a series of data words into a modulated signal}

The present invention relates to an apparatus and method for converting a series of data words into a modulated signal for recording and storing on a recording medium such as a magnetic disk, a magneto-optical disk or an optical disk.

In general, in order to record and store a series of data on a recording medium such as a magnetic disk, a magneto-optical disk, or an optical disk, the data is modulated into a code word sequence matched to the recording medium. When a DC component is included in the modulated codeword sequence, various error signals such as tracking errors generated in servo control such as a disk driver are biased or jitter easily occurs.

Therefore, the signal having the least direct current component must be recorded on the recording medium, because the recording channels do not normally respond to the low frequency component. On the other hand, suppressing low frequency components in a signal works very advantageously when reading out a signal from a recording medium on which the signal is recorded in a track, since continuous tracking control can be prevented from being disturbed by the recording signal. .

In addition, suppressing the low frequency component enables an improved tracking operation in which audible noise is reduced. For these various reasons, the modulated codeword sequence should not include the DC component as much as possible. The digital sum value has been proposed as a method for preventing the DC component from being included in the modulated codeword sequence. The control method is as follows.

First, as shown in FIG. 1, a general data modulation apparatus includes a codeword generator 10 for generating and outputting a data word that is a series of user data into a plurality of codeword sequences, and a DSV of the codeword sequences. And a codeword selector 20 for selectively outputting any one smallest codeword, and a recording signal modulator 30 for modulating and recording any one codeword having the lowest DSV into a recording signal.

Meanwhile, as illustrated in FIG. 2, the codeword generator 10 includes an augmentor 100 and a plurality of non return to zero inversion (NRZI) coders 101 to 116. configuration and the code word selector 20, and is configured including a plurality of code memory (201 _{1 1-216)} and DSV storage / calculation section (202 _{1-216 2),} and a selection unit 220. the

In the augmenter 100, a digital word of a predetermined predetermined number of bits, for example, different digital bits of four bits (T = 0000,0001 ... 1111) is selected from the front, middle, or trailing ends of the data word. Disposed at least in one part to generate 16 different intermediate sequences, and in the NRZI coders 101 to 116, binary recorded zeros indicate no change in the recording medium, and binary An NRZI coding operation is performed to indicate that '1' (One) recorded as is shifted in the opposite direction on the recording medium, thereby outputting respective codewords for the plurality of intermediate sequences.

Meanwhile, in the code memories 201 _{1 to} 216 ₁ included in the codeword selector 20, different codeword sequences generated and output from the codeword generator 10 are temporarily stored, respectively, and the DSV storage / calculation section (201 _{2-216 2),} and a direct current component of the current temporary code words stored in the code memory, and the accumulated value of the DC component cumulative DSV before for the previous code word, in that the current cumulative sum Will output the DSV.

In addition, the selector 220 selects a current DSV calculated by the DSV storage / calculation units 201 _{2 to} 2216 ₂ , that is, 16 DSVs for respective codewords stored in 16 code memories. In comparison with each other, any one codeword having the lowest DSV is selected and output.

Therefore, since any one codeword having the smallest DSV is selectively outputted to the recording signal modulator 30, the codeword having the least direct current component can be recorded and stored as a modulation signal matched to the recording medium.

However, if the codeword is selectively recorded through the above process, the number of consecutive '0' (Zero) between '1' and '1' among the data bit strings of the codeword may increase indefinitely. In this case, since there is a section in which the level change of the playback signal read out from the recording medium does not exist for a long time, the playback PLL (Phase Locked Loop) operation for that section becomes unstable, thereby preventing normal data playback operation. There is a problem that can not be.

Accordingly, the present invention was created to solve the above problems, and when selecting a codeword to be recorded on a recording medium such as a magnetic disk, a magneto-optical disk, or an optical disk, the present invention not only DSV, but also '1' of the data bit string of the codeword Provided is an apparatus and method for converting a series of data words into a modulated signal such that the number of consecutive '0's (Zeros) between' 1 'and' 1 'is limited, so that the reproduction PLL can be stabilized and data can be normally reproduced. There is a purpose.

The apparatus for converting a series of data words into a modulated signal according to the present invention for achieving the above object, after adding a different digital word to the input data word, and coding in a predetermined manner a plurality of codeword sequences Sequence generating means for generating; Digital sum calculating means for calculating a digital sum (DSV) for each of the generated plurality of codeword sequences; Penalty calculation means for calculating a penalty according to the number of '0's present between consecutive' 1's in each bit for the generated plurality of codeword sequences; And based on the sum of the calculated digital sum and the penalty. Characterized in that it comprises selection means for selecting one codeword sequence as a codeword sequence for recording,

 In addition, the method of converting a series of data words to a modulation signal according to the present invention, comprising the steps of adding a different digital word to the input data word, and then coding in a predetermined manner to generate a plurality of codeword sequences; Calculating a digital sum (DSV) of the generated plurality of codeword sequences, respectively, and calculating a penalty according to the number of '0's present between consecutive' 1's in each bit; And selecting one codeword sequence as a codeword sequence for recording, based on the sum of the calculated digital sum and the penalty.

Hereinafter, a preferred embodiment of an apparatus and method for converting a series of data words into a modulated signal according to the present invention will be described in detail with reference to the accompanying drawings.

First, as described above with reference to FIG. 1, the data modulation apparatus according to the present invention includes a codeword generator, a codeword selector, and a write signal modulator. As shown in Fig. 3, an augmenter 100 and a plurality of NRZI coders 101 to 116 are included, and the codeword selector 50 includes a plurality of code memories 501 _{1 to} 516 _1. ), The DS penalty storage units 502 _{1 to} 516 ₂ , and the selection unit 520 are further configured with K penalty calculation units 501 _{3 to} 516 ₃ .

On the other hand, the K penalty calculation unit 501 _{3 to} 516 ₃ calculates a penalty different from the number of '0' (Zero) consecutive between '1' and '1' in the data bit string of the codeword. To do this, run length limited (RLL) codes, generally denoted as (d, k) codes, i.e., at least '0's added between consecutive data'1's must be maintained. In an RLL code having a condition that '0' should not exceed k between '1', the corresponding penalty is calculated according to the number of '0' recorded between the consecutive '1'.

In the selector 520, the DSVs for the respective codewords calculated and output by the DSV storage / calculation units 501 _{2 to} 516 ₂ , and the K penalty calculation units 501 _{3 to} 516 _3, respectively. Comparing and checking the total penalty of the sum of the K penalty for each codeword to be calculated and outputted, and outputting any one codeword having the lowest total penalty, it will be described in detail as follows.

First, in the augmenter 100 of the codeword generator 10, a digital word of a predetermined predetermined number of bits, for example, different four-bit digital words (T = 0000,0001 ... 1111), 16 intermediate sequences that are different from each other are generated by arranging at least one of the front, middle, or trailing ends of the data word, and the NRZI coders 101 to 116 perform the NRZI coding operation described above with reference to FIG. In this case, each codeword for the plurality of intermediate sequences is output.

Meanwhile, in the code memories 501 _{1 to} 516 ₁ recorded in the codeword selector 50, different codeword sequences generated and output from the codeword generator 10 are temporarily stored, respectively, and the DSV storage is performed. / calculation section (501 _{2-516 2),} a current a direct current component of the current temporary code words stored in the code memory, and the direct current component and the cumulative value of the previous cumulative DSV for the preceding code words, the cumulative sum Will output the DSV.

In the K penalty calculation units 501 _{3 to} 516 ₃ , a data bit string of an arbitrary codeword selected and output by the selecting unit 520 and a current codeword temporarily stored in the code memory. K is proportional to the number (K) of '0' (Zero) present between '1' and '1' among consecutive data bit strings between the previous codeword and the current codeword Calculate the penalty (Kpen).

For example, the number K of '0' existing between the consecutive '1' is compared with the preset first and second reference values n, m and 0 <n <m, If the number K of '0' is greater than the first reference value n and less than the second reference value m, the number Kn of the '0' is multiplied by the first weight a, and the value '0' When the number of 'K' is greater than the second reference value m, the number Km of the '0' is multiplied by the second weight b, a <b, and the sum is added to the corresponding codeword. Calculated output as K Pen for.

That is, it is assumed that the data bit string of the codeword is '1001000010000001', the first reference value is n = 3, the second reference value is m = 5, and the first and second weight values are a = 0.3 and b = 0.7, respectively. The K penalty calculation unit detects and confirms the number K of consecutive '1's as' 2', '4', and '6', respectively, and is greater than n = 3. Multiplying the weight a = 0.3 for K = '4' less than m = 5, and multiplying the weight a = 0.7 for K = '6' more than m = 5, resulting in K for the codeword. The penalty Kpen = aKn + bKm = 0.3 x 4 + 0.7 x 6 = 5.4 is calculated and output.

For reference, the first and second reference values, the first and the weight (a, b) can be arbitrarily set by the designer designing the recording device, and also the continuous' The K penalty may be calculated and output using only one number K of the largest '0's present between 1'.

On the other hand, the DSV storage / calculation section (501 _{2-516 2),} the direct current component of the current temporary code words stored in the code memory, the accumulated value of the DC component before the cumulative DSV of the previous code word, The cumulative current DSV is output.

In the selector 520, the current DSV calculated and output from the DSV storage / calculators 501 _{2 to} 516 ₂ , that is, 16 DSVs for each codeword stored in 16 code memories, On the basis of the K penalty Kpen calculated and output by the K penalty calculation units 501 _{3 to} 516 ₃ , a value of '0' existing between '1's that are continuous in the data bit string of the codeword while having a small DC component Any one codeword having a small number is selectively outputted.

That is, the selector 520 adds up the DSV storage / calculation units 501 _{2 to} 516 ₂ and the DSV and K penalties calculated and output from the K penalty calculation units 501 _{3 to} 516 ₃ , respectively. By selectively outputting any one codeword having the smallest sum value (Tpen = DSV + Kpen), the recording signal modulator 30 has a '1' contiguous to the data bit string of the codeword with a small DC component. Any one of the codewords having a small number of '0's present between them can be modulated and then recorded on a recording medium such as a magnetic disk, a magneto-optical disk or an optical disk.

For reference, the selection unit may additionally assign different first and second weights to the DSV and the K penalty.

As mentioned above, preferred embodiments of the present invention are disclosed for the purpose of illustration, and those skilled in the art can improve and change various other embodiments within the spirit and technical scope of the present invention disclosed in the appended claims below. , Replacement or addition would be possible.

The apparatus and method for converting a series of data words according to the present invention constructed and constructed as described above are modulated by adding a different digital word to an input data word and then coding the same by a predetermined method such as an NRZI coding scheme. Computes the K penalty according to the number of '0's present between consecutive' 1's in each bit, Thus, the calculated sum of the DSV and K penalties may be recorded on a recording medium such as a magnetic disk, a magneto-optical disk or an optical disk by selecting one codeword sequence having a relatively small number as a codeword sequence for recording. When the codeword is selected, not only the DSV but also the number of consecutive '0's (Zero) between' 1 'and' 1 'in the data bit string of the codeword is limited, so that It is a very useful invention that can normally perform stability and data reproducing operations.

1 schematically illustrates a configuration of an apparatus for converting a general data word into a modulated signal,

2 illustrates a detailed configuration of a codeword generator and a codeword selector included in an apparatus for converting a general data word into a modulated signal.

3 illustrates a detailed configuration of a codeword generator and a codeword selector included in an apparatus for converting a data word into a modulated signal according to the present invention.

※ Explanation of code for main part of drawing

10: codeword generator 20,50: codeword selector

30: recording signal modulator 100: augmentor

101 to 116: NRZI coder 501 _{1 to} 516 ₁ : codeword memory

501 _{2 to} 516 ₂ : DSV storage / calculation unit 501 _{3 to} 516 ₃ : K penalty calculation unit

520: selection unit

Claims (9)

Sequence generating means for generating a plurality of codeword sequences by adding different digital words to an input data word and then coding them in a predetermined manner; Digital sum calculating means for calculating a digital sum (DSV) for each of the generated plurality of codeword sequences; Penalty calculation means for calculating a penalty according to the number of '0's present between consecutive' 1's in each bit for the generated plurality of codeword sequences; And Using the calculated digital sum and penalty. And a selection means for selecting one codeword sequence as a codeword sequence for recording. The method of claim 1, The sequence generating means includes: an augmentor for adding different digital words of N bits to an input data word, and a plurality of sequences to which the digital word is added are coded in an NRZI manner, so that 2 ^N codewords are used. And an NRZI coder (Coder) for generating a sequence. The method of claim 1, The penalty calculating means compares the number of '0's existing between consecutive' 1's with each other in a plurality of reference values within each bit in which a previously selected codeword sequence and a current codeword sequence are contiguous. After assigning different weights according to the reference value, the values are summed and calculated as a penalty according to the number of '0's for each codeword sequence. Device. The method of claim 1, The selecting means converts a series of data words into a modulated signal, selecting one codeword sequence having a relatively smallest sum between the calculated digital sum and a penalty as a codeword sequence for recording. Device. Adding different digital words to the input data word, and then coding in a predetermined manner to generate a plurality of codeword sequences; Calculating a digital sum (DSV) of the generated plurality of codeword sequences, respectively, and calculating a penalty according to the number of '0's present between consecutive' 1's in each bit; And And using the calculated digital sum and penalty, selecting one codeword sequence as a codeword sequence for recording. 3. The method of claim 5, In the first step, N-bit different digital words are added to an input data word, and then coded in an NRZI scheme to generate 2 ^N codeword sequences. Way. The method of claim 5, In step 2, the number of '0's existing between consecutive' 1's in each bit in which a previously selected codeword sequence and a current codeword sequence are consecutive are compared with a plurality of different reference values. The method of converting a series of data words into modulation signals by assigning different weights according to the reference values, adding the values, and calculating the penalty according to the number of '0's for each codeword sequence. . The method of claim 5, In step 3, a sequence of data words is converted into a modulated signal, wherein any one codeword sequence having a relatively smallest sum between the digital sum and the penalty is selected as a codeword sequence for recording. Way. The method according to any one of claims 5 to 8, And a codeword selected by the method is converted into a modulated signal.